A trainable transceiver is provided for a vehicle for transmitting signals to a device remote from the vehicle. The trainable transceiver includes a programmable oscillator for generating a signal having a selected reference frequency; an RF transceiver that receives an RF signal during a training mode in order to learn characteristics of the received RF signal, and transmits an RF signal to the remote device in an operating mode where the transmitted RF signal includes the learned characteristics of the received RF signal, wherein the RF transceiver receives the reference frequency from the programmable oscillator and uses the reference frequency to learn the characteristics of the received RF signal and for generating the transmitted RF signal; and a controller that, during the operating mode, selects frequency control data representing a frequency and selects the selected reference frequency for the programmable oscillator as a function of the frequency control data.

A wireless communication method and apparatus, and a radio frequency subsystem are provided. The apparatus includes a local oscillator circuit, configured to provide a local oscillator signal; a radio frequency transmitter coupled to the local oscillator circuit, configured to send a first signal on a first carrier based on the local oscillator signal provided by the local oscillator circuit; a radio frequency receiver coupled to the local oscillator circuit, configured to receive a second signal on a second carrier based on a local oscillator signal of a same frequency as the local oscillator signal provided by the local oscillator circuit; and a digital frequency converter coupled to the radio frequency transmitter and the radio frequency receiver, configured to provide a digital frequency conversion operation to compensate for a frequency difference between a center frequency of the first carrier and a center frequency of the second carrier.

Capturing, extracting and storing narrowband IQ data for later processing enables timely and efficient analysis. As wideband capture of RF information includes noise and non-signal elements, the present invention detects, extracts and stores narrowband IQ signals for later assessment. By transforming a high-volume data stream to a collection of smaller narrowband signals with greatly reduced storage and on-board processing requirements the present invention facilitates the capability to analyze signals of interest in an otherwise denied environment.

A radio frequency chip includes at least two signal generation circuits, at least three radio frequency transceiver circuits, and at least three intermediate frequency transceiver circuits. The at least two signal generation circuits include a first signal generation circuit and a second signal generation circuit. The first signal generation circuit and the second signal generation circuit are configured to generate radio frequency local oscillator signals in different frequency bands. Any radio frequency transceiver circuit receives only a radio frequency local oscillator signal from one signal generation circuit at a time. The radio frequency transceiver circuit is configured to perform conversion between a radio frequency signal and an intermediate frequency signal based on the received radio frequency local oscillator signal.

A radio frequency chip includes at least two signal generation circuits, at least three radio frequency transceiver circuits, and at least three intermediate frequency transceiver circuits. The at least two signal generation circuits include a first signal generation circuit and a second signal generation circuit. The first signal generation circuit and the second signal generation circuit are configured to generate radio frequency local oscillator signals in different frequency bands. Any radio frequency transceiver circuit receives only a radio frequency local oscillator signal from one signal generation circuit at a time. The radio frequency transceiver circuit is configured to perform conversion between a radio frequency signal and an intermediate frequency signal based on the received radio frequency local oscillator signal.

In at least one embodiment, an apparatus for wireless communication is provided. The apparatus includes a transceiver, a dedicated modem, a frequency converter, at least one controller and a bus. The transceiver receives a first wireless signal associated with a first predefined wireless communication standard and a second wireless signal associated with a second predefined wireless communication standard. The dedicated modem is capable of processing the first wireless signal. The frequency converter down converts a second frequency of the second wireless signal. The controller receives data on the second wireless signal and processes the data on the second wireless signal. The bus is configured to divert the data from the second wireless signal from being received at the dedicated modem by directly transmitting the data from the second wireless signal to memory. The controller is further programmed to access the memory for processing the data on the second wireless signal.

The present invention relates to a test method implemented by an item of equipment (10) comprising at least two radio-communication devices (12, 13) for testing at least one transmitter and receiver of said radio-communication devices. According to the invention, it comprises the following steps implemented for testing a transmitter (120) to be tested of a transmitting radio-communication device (12) and/or a receiver (131) to be tested of a receiving radio-communication device (13) of the same item of equipment (10), a step (E100) of transmitting a test signal in a transmission channel of said transmitter (120) of said transmitting radio-communication device (12), and a step (E200) of detection, in a reception channel corresponding to said transmission channel of said transmitter (120), of the test signal transmitted.

A method for determining phase continuity of a local oscillator signal generated using a frequency divider is provided. The method includes determining at least one sample of the local oscillator signal. Further, the method includes determining information on the phase continuity using the at least one sample.

A method for determining phase continuity of a local oscillator signal generated using a frequency divider is provided. The method includes determining at least one sample of the local oscillator signal. Further, the method includes determining information on the phase continuity using the at least one sample.

A switching network and associated method for operating within a transceiver are disclosed. The switching network has a timing control circuit that offsets the time at which a through switch and a shunt switch transition between on and off states. The output of the timing control circuit is an inverted and delayed version of a control signal applied to the input of the timing control circuit. Controlling the timing of the shunt switch provides a means to safely discharge any accumulated charge within the capacitance C.sub.gs between the gate and source of transistors included within the through switch.